US20090115401A1

US20090115401A1 - System comprising an automotive fuse and an A/D converter

Info

Publication number: US20090115401A1
Application number: US10/593,708
Authority: US
Inventors: Dietmar Hoch; Christian Biberger; Hardo Tumm
Original assignee: Audi AG
Current assignee: Audi AG
Priority date: 2004-03-25
Filing date: 2005-03-23
Publication date: 2009-05-07
Also published as: EP1733410A1; JP4679571B2; WO2005093773A1; DE502005006327D1; EP1733410B1; JP2007531211A; DE102004014662A1; US7929267B2

Abstract

The invention relates to a system which comprises an automotive fuse and an A/D converter. Conventional systems comprising an automotive fuse and an A/D converter are designed such that a measured value is generated at the automotive fuse, which value is then amplified and passed on to the A/D converter via a long signal line. The novel space-saving system is characterized in that the A/D converter is located in close vicinity to the automotive fuse. The automotive fuse supplies the non-amplified, analog measured value for the input of the A/D converter. Signal transmission is carried out digitally via a bus system. It is especially advantageous if all components are housing in a common housing. Signal transmission is then carried out digitally via a bus system. The inventive system is suitable for use in data bus systems of vehicles.

Description

The invention relates to a system comprising an automotive fuse and an analog/digital converter according to the preamble of claim 1.
DE 299 11 177 U1 discloses a system with a measurement interface which detects and digitizes analog signals. This measurement interface is connected to a data bus which transmits the digitized measured values to other function units. The measurement interface for this purpose measures for example a time-variable voltage or time-variable current. This analog measurement signal or a signal proportional to it is then digitized by way of an analog/digital converter (A/D converter).
But in this connection the disadvantage is that special measurement devices, especially measuring shunts, which otherwise have no other functions, are required for this purpose. This measurement device and also the measurement interface require space.
Furthermore, systems are known which detect the voltage drop on a measuring shunt which also performs the function of a fuse. This analog measurement signal is amplified and then relayed to a central measurement system by way of a long signal line.
The disadvantage in this system is that as a result of incident electromagnetic radiation onto long signal lines and/or the use of additional amplifiers the measurements become inaccurate or adversely affect the fuse function of the automotive fuse, when it is used as a measuring shunt. Moreover these systems are very complex with respect to wiring, since each measurement point must be wired separately. Since the known central measurement systems assume larger dimensions, there is no mobility or it is greatly limited, i.e., these systems are only suited to laboratory structures.
The object of the invention is to devise a system with an automotive fuse and an A/D converter with which on the one hand accurate measurements for relay to a data bus system can be achieved without influencing the fuse function for which a wire or a sheet is destroyed at overly high loading.
This object is achieved in that an A/D converter is connected directly at its input to the automotive fuse, said converter digitizing the analog measurement value measured here immediately and on site and then making available this digital value for further processing.
The advantage of this configuration consists in that this system works without error, delivers exact measured values, is for the most part invulnerable to electromagnetic radiation and can be built to save space. The digital value determined with precision from the analog measured value can be transmitted error-free even over greater distances, for example with a bus cable.
Advantageous developments arise from the dependent claims. In this context it is especially advantageous if the automotive fuse and the A/D converter are located in a common housing and this housing is a standard automotive fuse housing. Other advantages accrue when a processor receives the digitized measured value from the A/D converter, its being advantageous when this processor is likewise located in the vicinity in the same housing as the automotive fuse and the A/D converter. Here it is advantageous that a temperature sensor for determining the ambient temperature is located on the automotive fuse used as a measuring shunt in the immediate vicinity, and optionally in the same housing as the automotive fuse, in order to be able to subject the analog or digitized measured value to temperature compensation.

The invention will be explained using embodiments which are shown in the figures.

FIG. 1 shows a bus system with several systems as claimed in the invention

FIG. 2 shows a system with an automotive fuse and an A/D converter for digitizing measured values

FIG. 3 shows a board with a system for digitizing of measured values

FIG. 4 shows housing shapes for systems for digitizing the measured values with integrated automotive fuse.

FIG. 1 shows several systems 1 as claimed in the invention which are connected to a bus system 2. The systems 1 which consist at least of one automotive fuse and an A/D converter are connected to the data bus 2. The systems 1 are in contact with control devices, circuits, function units, or similar devices which must be protected against overly high electrical loads via an automotive fuse. These devices produce signals which must be made available to the vehicle electronics for further processing. These signals must be measured and checked. In this connection, checking means that the signal level cannot cause damage. For this reason, as described later, an automotive fuse is needed. The system 1 digitizes the measured signal value and conditions it such that it can be sent by way of the data bus 2 for further processing. Likewise the data bus 2 supplies the systems 1 with the required voltage which can be tapped on a two-wire bus system. Furthermore, on the data bus 2 there is the level converter with the power supply 3 which in turn supplies the bus line 2 with power and which converts the digitized signals resulting from the determined measured values again and sends them to a master unit 4. This master unit 4 can be for example a personal computer (PC) or a personal digital assistant (PDA) which acquires the different signals, further processes them, and optionally based on the consequent results sends commands to the bus line for relay to the corresponding control devices, function units, or similar devices.
FIG. 2 shows one embodiment for a system with an automotive fuse and an A/D converter for digitizing of measured values. The system 1 consists of an automotive fuse 5 which is available for example in a 5A, 10A, 20A, or 30 A version. This fuse 5 consists essentially of a conductor sheet or conductor wire which is melted or in some other way destroyed if an overly large current flows via it. In the immediately vicinity of the fuse 5 is the A/D converter 6. The A/D converter 6 is a 24 bit converter which has a LSB value of 70 nV (LSB=least significant bit). The input 7 of the A/D converter 6 is connected to the automotive fuse 5. This means that the measured value to be digitized is tapped on the fuse 5. The fuse 5 and the input 7 of the A/D converter 6 form the analog part 11 of the system 1. The analog measured value which is measured on the fuse 5 in the embodiment is the voltage on the fuse resulting in a flowing current or an analog voltage in a measurement without a fuse.
Furthermore, the A/D converter 6 is connected to a voltage unit 12 which makes available both the supply voltage and also the reference voltage for the A/D converter 6. In the embodiment the reference voltage is 1.2 V and the supply voltage is 5 V. In the A/D converter 6 the analog measured value is converted into a digital value; this digital value can be read out at the output 8 of the A/D converter 6. In the embodiment the A/D converter 6 is in contact with a processor 9, this processor 9 further processing the digital output value 8 of the A/D converter 6. This processor 9 is also connected to a temperature sensor 10 which determines the ambient temperature in the vicinity of the fuse 5. In the processor 9 temperature compensation takes place together with the determined temperature value. The available digital measured value of the converted analog value is evaluated by the processor 9 which is located in the immediate vicinity of the A/D converter 6 and if necessary is sent to a computer 4 via the bus system 2. At the same time, the temperature of the fuse 5 which is used for temperature compensation of the measured value is detected. The processor 9 in this embodiment assumes control of the A/D converter 6, computation of the current impressed via the voltage drop of the original fuse wire, and command-controlled communication and data transfer to the computer 4. The control of the A/D converter 6 includes read-out of data and adjustment of parameters of the A/D converter of this module. The computation includes conversion of the A/D value from the converter into a temperature-compensated current value. In this connection the measured temperature is used for temperature compensation of the A/D measured value. This takes place using a temperature-current characteristic field which is located for example in the nonvolatile storage of the processor 9. Data transfer to the computer is controlled by commands. The current can be synchronously measured, i.e., all fuses receive the command to measure and begin simultaneously with the measurement. Afterwards, the subscribers 1 on the bus 2 are read out in succession by the computer 4. Furthermore, in this embodiment there is electrical isolation 13 in the system 1. The electrical isolation 13 has an optical coupler 15 which sends the output signal from the processor 9 to the data bus 2, complete electrical decoupling from the fuse wire taking place. Furthermore, the electrical isolation 13 has a direct current-direct current converter (DC-DC converter) 14 which supplies the voltage unit 12 with power. The supply unit of the voltage unit 12 also supplies the processor 9 with power.
FIG. 3 shows a board with a system as shown in FIG. 2. In this embodiment the top of the board 17, which together with the bottom contains the complete system 1, is shown. Here, on the top are the conventional original automotive fuse 5, the A/D converter chip 6, the processor 9, the optical coupler 15 for electrical isolation of the bus system, and the plug 18 for linkage to the power supply and the serial bus system. With this system, very high measurement accuracy which had not been achieved with conventional measurement systems in the past can be attained. This structure can have for example the following technical data. Therefore this board can furthermore be used as a normal fuse and also fits into the fuse compartment for an automotive fuse in the vehicle. The technical data for this structure are the following, for example:


Measurement range, current:	This corresponds to the inserted fuse of type 5 A, 10 A, 20 A,
	or 30 A. The total current can be measured.
Measurement range, voltage:	+/−60 volt (for measurement of an analog voltage without Si
	wire)
Measurement range, temperature:	−40° C. to +80° C.
Accuracy:	+/−100 μA, noise approx. +/−50 μA
Measurement method:	Original fuse wire as measuring shunt, digitization on the
	A/D converter and computation in the computer part directly
	on the fuse
Decoupling:	Complete decoupling of the vehicle by a direct current-direct
	current voltage supply and optically-decoupled signal lines
Number of measurement sites:	Up to 200
Output measurement values:	Measured current, temperature on fuse
Measurement cycle:	Synchronous measurement, asynchronous data transmission,
	100 measurement points are read out per second (fast
	measuring), one individual measurement with individual
	interrogation lasts approx. 200 ms
Temperature range:	−40° C. to 80° C. (application conditions)
Size of measurement strip:	approx. 14 mm × 30 mm
Bus system:	2-wire, serial
Interface:	RS232C
System configuration:	25, 50, or 100 measurement points, heterogeneous system
	with current, voltage and temperature measurement points on
	the same bus.

With this structure it is possible to convert an analog measured value into a digital value and to digitally send this value for example via a bus system to other units, for example control devices, without transmission being faulty.
FIG. 4 shows different housing shapes for this system. The housings 16 correspond in dimensions to those of conventional automotive fuses. But inside they have at least one A/D converter 6 or even a board 17, as is shown in FIG. 3. This system can be positioned in a space-saving design at the same location at which the automotive fuse alone had been positioned previously. This yields a space-saving and economical structure.
With this measurement system it is possible to acquire measured values about the original commercial fuses located in the vehicle in operation without major wiring costs and with very high precision. The measured values are detected in analog form. Immediately afterwards the analog measured value is digitized and only then further processed.
This system can be used on a mobile basis and can remain in the vehicle without influencing the original fuse function of the automotive fuse.
This fuse module is especially advantageous in test vehicles which can remain there during the entire trial lifetime. But these systems can also be used for mass production vehicles.

Claims

1. System comprising an automotive fuse for interrupting at least one circuit in overload and at least one analog/digital converter for detecting and converting an analog measured value which is supplied at the input of the analog/digital converter into a digital measured value which is made available for further processing at the output of the analog/digital converter, wherein

the input of the analog/digital converter is connected directly to the automotive fuse, the automotive fuse producing the analog measured value for the analog/digital converter, and

the analog/digital converter being located in the immediate vicinity of the automotive fuse in order to digitize the measured value directly after its detection.

2. The system of claim 1, wherein the automotive fuse and the A/D converter are located in a common housing.

3. The system comprising an automotive fuse and an analog/digital converter as claimed in claim 1, further comprising a processor connected to the output of the analog/digital converter on which the digitized measured value is present.

4. The system comprising an automotive fuse and an analog/digital converter as claimed in claim 2, further comprising a processor in the common housing of the automotive fuse and the analog/digital converter.

5. The system comprising an automotive fuse and an analog/digital converter as claimed in claim 1, further comprising a temperature sensor (10) in the vicinity of the automotive fuse.

6. The system comprising an automotive fuse and an analog/digital converter as claimed in claim 2, further comprising a temperature sensor in the common housing of the automotive fuse and the analog/digital converter.

7. The system comprising an automotive fuse and an analog/digital converter as claimed in claim 5, wherein the temperature sensor is connected to the processor in order to carry out temperature compensation on the measured value.

8. (canceled)

9. A digital transducer for a data bus system comprising the system of claim 1.

10. A system for measuring and transmitting values in a motor vehicle, the system comprising:

a data output device connected to a data bus, the data bus comprising:

at least one fuse connected directly to an A/D converter; and

a master unit for receiving data from the A/D converter.

11. The system of claim 10, wherein the master unit comprises at least one selected from the group consisting of a personal computer and a personal digital assistant.

12. The system of claim 10, wherein the data output device is selected from the group consisting of control devices and function units.

13. The system of claim 10, further comprising:

a processor in communication with the A/D converter; and

a temperature sensor, positioned to measure ambient temperature in the vicinity of the fuse.

14. The system of claim 10, wherein the at least one fuse and the A/D converter are contained in a common housing.

15. A method of measuring and transmitting data in a motor vehicle comprising:

transmitting analog data from a device through a fuse directly to an A/D converter;

digitizing the data in the A/D converter; and

passing the digitized data to a unit for further processing.

16. The method of claim 15, further comprising compensating the digitized data based upon ambient temperature in the area of the fuse.

17. The method of claim 15, further comprising collecting the analog data from a device selected from the group consisting of control devices and function units